Method and apparatus for beam steering in a wireless communications systems

ABSTRACT

A med and apparatus is provided that allows M transceivers to transmit/receive using M2 N  distinct beams using passive beam steering. This provides for the use of arbitrary narrow beams with a number of transceivers that is a fraction of the number of beams but ensures 360° coverage. In other words it permits significant improvements in the link budget with a minimal rise in the cost of the BS. The apparatus includes M distribution switches applied 2 N  passive beam forming networks each coupled to M antennas. The method and apparatus ate compatible with TDMA in the downlink and in the uplink.

FIELD OF THE INVENTION

The present invention relates to wireless communication systems and is particularly concerned with beam steering.

BACKGROUND OF THE INVENTION

An essential part of any wireless link is the design of the antenna and the choice of its beam width (or angle) and its gain. In general antennas with narrower beam provide higher gains.

The gain of the antenna contributes twice in the, link budget: both at transmission and at reception. At transmission, the effective incident radiated power (EIRP) [dBm] is the sum between the antenna gain G_(T) [dBi] and the transmitter power P [dBm]. EIRP [dBm]=P [dBm]+G_(T) [dBi]

At reception, the signal level S[dBm] at input of the receiver is the sum between the antenna gain G_(R) and the transmitted EIRP minus the path loss PL [dBi]. S [dBm]=G_(R) [dBi]+EIRP [dBm]−PL [dBi]

The link budget and consequently the coverage can be improved by raising the transmitter power P or by raising the antenna gains G_(T) or G_(R). For a transceiver that use the same antenna to transmit and receive, i.e. G_(T)=G^(R), increasing the antenna gain has positive effects on both transmission and reception while increasing the power improves only the transmission. For symmetric links (all participant systems have the same P and G_(T)=G_(R)), increasing the antenna gain has double effect than increasing the transmitter power P.

The EIRP in each frequency band is usual limited by regulatory bodies like Federal Communications Commission in USA. In such cases, the only way to improve the link budget and the coverage is to raise the gain of the antenna at the receiver G_(R).

When EIRP is limited, rising the antenna gain at the transmitter G_(T) has to be associated with a corresponding reduction in the power of the transmitter P and implicitly a reduction in the cost of the power amplifier (PA).

Antennas with narrower beams provide more spatial selectivity, which in turn, improves the system immunity to interference.

With current technologies, the advantages of using high-gain, narrow-beam antennas are offset in the design of a base-station (BS) by the price of the transceivers needed to obtain 360° coverage. For example, a 23 dBi pencil-beam (same beam width in the vertical and horizontal plane) antenna will have a beam with of only 14°. Thus, in order to ensure 360° coverage with current technologies, we would need 26 antennas and consequently 26 transceivers.

It is known in wireless systems to use beam forming to emulate a high gain antenna using multiple low-gain antennas. This is achieved using a system as depicted in FIG. 1. A wireless system 10 includes a transceiver 12 coupled to a phase-delay passive network, 14 coupled to a plurality of antennas 16 as in the system of FIG. 1. A phase-delay network is inserted between the transceiver and the antennas.

In operation, at transmission, the phase-delay network 10 distributes the signal from the transceiver 12 to all antennas 16. At reception the network combines the signal received from all antennas 16 and passes the resulting signal to the transceiver 12. The phase and delay for each antenna are established in accordance with the position of the antennas such that the desired beam width and direction are obtained.

An extension of the passive beam forming uses of several transceivers 12 with multiple-input phase-delay network. It has been shown that such a network can be implemented and produces beams with gain higher than of the constituent antennas if:

-   -   1. The number of transceivers does not exceed the number of         antennas.     -   2. The transceivers operate on close but different frequencies         to avoid cross-talk between beams.

Referring to FIG. 2, there is illustrated a known wireless system for active beam steering. The wireless system 20 includes a transceiver common part 22 coupled to an electronically controlled phase delay active network 24 coupled to a plurality of transceiver RF parts 26 each coupled to a corresponding one of a plurality of antennas 28.

Active beam steering is another extension of beam forming, in which the phase-delay network is electronically controlled. By trimming phases and delays, the resulting beam can be steered into the desired direction.

Both known beam forming of FIG. 1 and steering of FIG. 2 require precise amplitude, phase and delay control in the phase-delay network. They also require precise alignment of the antennas and precise amplitude, phase and delay matching between RF cables. In practical systems, the precision of these elements is the most important factor that limits the achievable antenna gain. Precision is especially hard to maintain with beam steering where phase and delay parameters are variable. Practical implementations of beam steering use phase-delay networks implemented in base-band processors to ensure precise delay and phase control. Therefore in active beam steering systems the RF part of the transceiver is replicated for each antenna, as shown in FIG. 2.

Active beam steering systems are very expensive because they require replication of the RF subunit for each antenna when multiple antennas are used to achieve a single beam.

Even with the phase-delay network implemented in base-band, the active beam-steering systems require precise amplitude, phase and delay matching between RF subunits. In practice, errors occur and this seriously limits the maximum achievable antenna gain.

A further concern is that the active beam steering system of FIG. 2 offers no upgrade path. In order to add a second beam, one must add an entire new system with multiple RF subunits and multiple antennas in addition to the new transceiver. This could be an important limitation during wireless system deployment.

Active beam steering may not be compatible with current standards for wireless broadband access. In FIG. 3, an example of an air interface for a wireless system illustrated in a functional block diagram. The air interface 30 includes a downlink portion 32 and an uplink portion 34. The downlink portion begins with a broadcast segment 36 followed by a plurality of unicast segments 38. The uplink portion 34 includes a contention window 40 and a plurality of scheduled uplinks 42.

As shown in FIG. 3, these standards, e.g. IEEE802.16, employ downlink broadcast messages that must be sent from the base-station (BS) to all subscriber stations (SS) at the same time. They also employ uplink contention windows during which BS has to “listen” for new SSs without knowing the direction in which it must steer the beam. In order to support these features, the beam must be made 360° wide during these periods. This may not be acceptable or even possible because, for example, enlarging the beam from 22° to 360° causes a reduction of the antenna gain of at least 12 dB.

SUMMARY OF THE INVENTION

Accordingly the present invention provides a method and apparatus that allows M transceivers to transmit/receive using M2^(N) distinct beams using passive beam steering.

Advantageously the present invention allows use of arbitrary narrow beams with a number of transceivers that is a fraction of the number of beams but ensures 360° coverage. In other words it permits significant improvements in the link budget with a minimal rise in the cost of the base station.

Advantageously the present invention entails a method that does not require precise positioning of the antennas and does not require amplitude, phase or delay matching in the RF cabling.

Advantageously the present invention entails a method that does not require replication of the RF stages.

Advantageously the present invention entails a method and apparatus that allows easy, hot upgrade from M to M+1, M+2 and so on up to M2^(N) transceivers.

Advantageously the present invention entails a method and apparatus that allows hot downgrade from any number of transceivers grater than M+1 down to M transceivers. Also downgrade paths can be used to provide a fail-safe system.

Advantageously the present invention provides for both upgrades and downgrades to be performed without affecting the antenna or the beam gain as seen by each subscriber station. In other words upgrades and downgrades are performed without affecting the RF link budget.

Advantageously the present invention entails a method and apparatus that are described as applied at RF but it can also be seamlessly applied at IF or base-band. However the cost of the system is minimized when invention is applied at RF.

Advantageously the present invention entails a method that is compatible with existing-wireless broadband access standards and that supports broadcast messages in the downlink and contention windows in the uplink without changing the antenna gain and the link budget.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features of the invention will become more apparent from the following description in which reference is made to the appended drawings.

FIG. 1 illustrates a known wireless communications system with passive beam forming;

FIG. 2 illustrates a known wireless communications system with active beam steering; and

FIG. 3 illustrates a known air interface for a wireless communications system;

FIG. 4 illustrates a wireless communications system in accordance with an embodiment of the present invention;

FIGS. 5 a and 5 b illustrate examples of grouping for M2^(N)=16, for the wireless system of FIG. 4;

FIG. 6 illustrates in further detail the distribution switch of FIG. 4;

FIG. 7 illustrates all useful configurations for the switch of FIG. 6;

FIG. 8 illustrates an 8-way distribution switch;

FIG. 9 illustrates the upgrade-downgrade paths for the distribution switch of FIG. 8;

FIG. 10 illustrates an implementation of the cross switch of FIGS. 6 and 8;

FIG. 11 illustrates an implementation of the straight-switch of FIGS. 6 and 8;

FIG. 12 graphically illustrates operation of the transceiver using TDMA; and

FIG. 13 illustrates in a block diagram the downlink and uplink detail for one beam.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to FIG. 4, there is illustrated a wireless system in accordance with an embodiment of the present invention. The wireless system 50 includes a plurality of transceivers 52 a-m coupled to a corresponding plurality of distribution switches 54 a-m. Distribution switches 54 a-m each having 2^(N) outputs for coupling to corresponding inputs of 2^(n) passive beam forming networks 56 each passive beam-forming network 56 is connected to a plurality M of antennas 58. Each of the plurality of transceivers 56 a-56 m may include 2^(N) transceivers.

The system of FIG. 4 thus uses M2^(N) high-gain antennas 58 that are first grouped in 2^(N) groups of M antennas each. Each group of M antennas is processed by one beam-forming network 56 to form M high-gain beams. Note, that an embodiment of the invention may be applied without the beam-forming network, in which the beam width and gain are equal to the antenna angle and gain. However, in most cases when a large number of antennas are used the beam-forming network 56 will be used to reduce significantly the cost of the antenna system.

In operation, the resulting M2^(N) beams operate on M different frequencies to ensure proper operation of the beam-forming network.

Each group of 2^(N) beams operating on the same frequency is processed through a distribution switch 54 that allows 1, 2, 3, and up to 2^(N) transceivers 52 to control the 2^(N) beams.

The passive beam steering permits a top-down approach to the design of an upgradeable base stations (BS). The designer chooses the beam angle (width) BA based on the performance of the beam forming technology and the antenna availability. The designer also chooses the minimum overlapping angle OA between adjacent beams. Then, 360°/(BA−OA) gives the minimum number of sectors needed in the system. The designer chooses M and N such that: M2^(N)≧360°/(BA−OA)

The antenna system of FIG. 4 provides M2^(N) beams circularly placed at angles of 360°/M2^(N) one to each other. The beams are divided into M groups: G₁, G₂, . . . , G_(M), each having 2^(N) beams. If beams are numbered in circular order from 1 to M2^(N), then G₁ will contain beams B₁1=1, B₁2=M+1, B₁3=2M+1, . . . , while G₂ will contain beams B₂1=2, B₂2=M+2, B₂3=2M+2, . . . , etc. Each group of antennas operates on the same frequency and different groups will operate on different frequencies.

Referring to FIGS. 5 a and 5 b there are illustrated examples of grouping for M2^(N)=16. Note that M=8, N=1 and M=16, N=0 are also possible solutions. FIG. 5 a shows M=4, N=2 and FIG. 5 b shows M=2, N=3.

Each group of beams is processed by one distribution switch 54 that allows 1, 2, . . . , or 2^(N) transceivers 52 to cover all subscriber-stations in all 2^(N) beams. This is achieved using time-division-multiple-access (TDMA).

Referring to FIG. 6, there is illustrated in further detail the distribution switch of FIG. 4. The four way distribution switch. 54, for N=2, includes a plurality of inputs 60 a-60 d for coupling to corresponding transmitters T1-T4 and a plurality of outputs 62 a-62 d for coupling to corresponding beams B1-B4. The four way distribution switch 54 includes first and second cross switches 64 and 66 coupled in series between inputs 60 a and 60 b and outputs 62 a and 62 b. A third cross switch 68 coupled to outputs 62 c and 62 d having a first input coupled to a second output of cross switch 64. The distribution switch 54 also includes straight switches 70 and 72. Straight switch 70 coupled to input 60 c and 72 coupled to input 60 d. Straight switch 70 has an output coupled to a second input of cross switch 66 and straight switch 72 has an output coupled to a second input of cross switch 68.

The distribution switch is important because it connects one group of 2^(N) beams to one transceiver or 2 transceivers or so on up to 2^(N) transceivers. To understand its operation we use an example for N=2, then we show how it can be extend to N=3, 4, etc.

FIG. 6 shows the structure of the 4 -way distribution switch (i.e. N=2). In operation, it connects 4 beams B1, B2, B3 and B4 to one, two, three or four transceivers: T1, T2, T3, T4. The distribution switch is built with 3 cross-switches: XS20, XS10 and XS11(64, 66, 68), and two straight switches SS21 a and SS21 b (70,72).

The cross switches (64, 66, 68) can be configured in two modes:

-   -   1. Straight: port A connects port C and port B connects port D     -   2. Cross: port A connects port D and port B connects port C

The straight switches (70,72) can be used to introduce additional isolation when either T3 (60 c) or T4 (60 d) are not in use, or they can be simple shorts connecting their port A with port B. More details can be found below, where the construction of these switches is described. Both straight-switches and cross-switches introduce substantially no insertion loss (except those due to imperfections).

When deploying the system, the service provider may initially decide that a single transceiver 52 a ₁ is enough to cover all four beams. The transceiver is connected to T1(60 c) and the BS controller instructs the distribution switch 52 that T1 can manipulate all cross switches. Therefore, T1 covers all four beams: B1, B2, B3 and B4 using the following configurations: Configuration XS20 XS10 XS11 Mode Description Straight Straight — Tx or T1 transmits/receives through B1 Rx Straight Cross — Tx or T1 transmits/receives through B2 Rx Cross — Straight Tx or T1 transmits/receives through B3 Rx Straight — Cross Tx or T1 transmits/receives through B4 Rx

When the service provider (sp) determines that the single transceiver 52 a ₁ is overloaded, i.e. the data bandwidth provided by one transceiver is not enough,. the sp can upgrade the system to two transceivers. The second transceiver 52 a ₂ is added to port T2 without interfering with the operation of the existing transceiver 52 a ₁. The BS controller configures XS20 (64) as straight (A connects C and B connects D) and instructs the distribution switch 54 a to allow T1 (60 a) to control XS10 (66) and T2 (60 b) to control XS11 (68). Therefore, T1 (60 a) covers two beams: B1 and B2, and T2 (60 b) covers the other two beams: B3 and B4.

Depending on the service growth, the service provider may need to further upgrade the system. If T1 (60 a) is overloaded, a third transceiver 52 a ₃ can be added at port T3 (60 c); the BS controller configures XS10 (66) as straight and will leave T2 (60 b) to control XS11 (68) (XS20(64) was already configured straight); T1(60 a) covers beam B1, T3 (60 a) covers B2, and T2 (60 b) covers B3 and B4. If T2 (60 b) is overloaded, a transceiver can be added at port T4 (60 d); the BS controller configures XS11(68) as straight and leaves T1(60 a) to control XS10 (66); T1(60 a) covers B1 and B2, T2(60 b) covers B3, and T4(60 d) covers B4. Finally, if all four transceivers are used, the BS controller configures all 3 cross switches (64,66,68) as straight and does not let any transceiver to control any cross switch. Then, T1(60 a) covers B1, T2 (60 b) covers B3, T3(60 c) covers B2 and T4(60 d) covers B4.

The same paths used to upgrade to more transceivers can also be used to downgrade to fewer transceivers. The distribution switch 54 offers many other configurations that can be used for making the system 50 fail safe.

Referring to FIG. 7 there is illustrated all useful configurations that can be obtained with the 4-way distribution switch. The five white blocks show the configurations discussed above, i.e. the upgrade-downgrade paths. The shaded configurations are not recommended for upgrade/downgrade; which provides the same functionality as the white, but for non-shaded configurations there is less upgrade/downgrade flexibility. However, shaded configurations can be used to provide back-off possibilities in the event that one or more transceivers fail. With two or more transceivers installed in -the system, if any of the transceivers fails, the distribution switch can always be reconfigured such that the remaining transceivers cover all beams. When all transceivers are installed, the system becomes immune to failure of any two transceivers.

Referring to FIG. 8 there is illustrated an 8-way distribution switch (N=3). The 8-way switch includes eight inputs 60 a, . . . 60 i for transceivers T1, . . . T8 and eight outputs 62 a, . . . 62 i for beams B1, . . . B8. Between inputs 60 a and 60 b and outputs 62 a and 62 b are three cross switches 74, 64, and 66, each having first and second inputs (A, B) and first and second outputs (C, D) series connected at first inputs/outputs. A fourth cross switch 68 has its first and second outputs series connected to the outputs 62 c and 62 d cross switch 80 has its first and second outputs coupled to the outputs 62 e and 62 f. A seventh cross switch 82 has its first and second outputs coupled to outputs 62 g and 62 h, respectively. The input 60 b is connected to the second input (B) of the cross switch 74, whose second output (D) is connected to the first input (A) of cross switch 78. The input 60 c is coupled via a straight switch 90 to the second input (B) of cross switch 64, whose second output (D) is connected to the first output (A) of cross switch 68. The input 60 d is coupled via a straight switch 92 to the second input (B) of cross switch 78, whose second output (D) is connected to the first input (A) of cross switch 82. The input 60 e is coupled via straight switches 94 and 96 to the second input (B) of cross switch 66 whose second output (D) is connected to the output 62 b. The input 60 f is coupled via the straight switches 98 and 100 to the second input (B) of cross switch 68. The input 60 g is coupled via the straight switches 102 and 104 to the second input (B) of cross switch 80. The input 60 h is coupled via the straight switches 106 and 108 to the second input (B) of cross switch 82.

The 8-way distribution switch is constructed with two 4-way distribution switches, whose T1 ports are passed through the cross-switch XS30(74) to obtain the T1(60 a) and T2(60 b) ports for the 8-way distribution switch. The other three T ports in each of the 4-way switches are passed through straight-switches to obtain the T3. . . T8 ports for the 8-way switch. Using the same rule, two 8-way switches can construct a 16-way distribution switch (N=4) and so on.

Referring to FIG. 9 there is illustrated the upgrade-downgrade paths for the 8-way distribution switch of FIG. 8. The switch can connect any number of transceivers between 1 and 8 (60 a-60 h). The service provider has the option of upgrading the system only when needed. If a transceiver is overloaded and covers two or more beams, its payload can always be split with a newly added transceiver. Both the upgrades and the downgrades do not require system shutdown and can be performed without any interruption of the ongoing communications.

When using more than one transceiver, if one transceiver fails, the switch can be reconfigured such that all beams are covered.

Similarly a 2^(N)-way distribution switch can be built that allows transceivers T1, T2 to cover 1, 2, 4, . . . , 2^(N) beams, transceivers T3, T4 to cover 1, 2, . . . , 2^(N−1), T5, T6, T7, T8 to cover 1, 2, . . . , 2^(N−2) and so on. The fail-safe feature comes from the fact that. for each sub-tree there are two transceivers that can cover the entire sub-tree.

Based on the structure of the switch, the number of beams that a particular transceiver covers in any configuration is always a power of 2. This helps with the development of the algorithms that will reside in each transceiver and will ensure coverage of the required number of beams.

FIG. 10 shows a possible implementation of the cross-switch 64 of FIGS. 6 and 8 using two single-pole-dual-terminal (SPDT) RF/IF switches (112, 114). When both SPDT switches are in ‘0’ position, the cross-switch is in straight mode. When both SPDT switches are in ‘1’ position, the cross-switch is in cross mode.

Depending on the performance required for the straight-switches in terms of insertion-loss and isolation, the straight-switch can be:

1. a simple short (switch is always closed)

2. an single-pole-single-terminal (SPST) RF/IF switch with no impedance matching

3. an SPST RF/IF switch with impedance matching.

FIG. 11 shows a possible implementation of the straight-switch 70 of FIGS. 6 and 8 as an SPST switch 122 with impedance matching. The implementation uses a 4-terminal dual-pole-dual-terminal (DPDT) RF/IF switch 122 as switching element. With the DPDT switch, if terminal 1 is connected to 4, then the straight-switch is closed (ports A and B are connected); if terminal 1 connects to 3 and terminal 2 to 4, then ports A and B are disconnected and each of them is terminated to ground with an impetitive (124,126) Z₀ (e.g. 50Ω). To obtain an SPST switch without impedance matching, the two termination impedances Z₀ are removed from the circuit and the DPDT switch is replaced by a simple SPST switch (placed between terminals 1 and 4).

In order to cover 2^(n) beams: B1, B2, . . . , B2 ^(n), a transceiver T accesses the beams using time-division-multiple-access (TDMA). To implement this, T emulates one media-access-control (MAC) layer for each beam. All MACs operate with the same frame length but the frames are shifted in time. Each MAC produces its own downlink (DL) and its own uplink (UL). For maximum efficiency T concatenates all 2^(n) downlinks in a long DL and all uplinks in a long UL. The operation is depicted in FIG. 12 where T denotes the signal at the transceiver and Bi denotes the signal going to or expected to come from beam Bi. The downlink and uplink details for one beam are shown in FIG. 13 in a block diagram.

Note that it not necessary to group the uplink bursts by beam. The system will have the same performance if the uplink bursts are not grouped by beam. However, since the downlink on each beam uses time-division-multiplexing (TDM), i.e. all downlink packets are concatenated in a single RF burst, it is more efficient to group the downlink packets by beam.

According to current standards for broadband wireless access, each subscriber station (SS) synchronizes on the beginning of the downlink and considers this to be the beginning of a MAC frame. Each SS checks for the MAC frame length as it is announced by the base-station (BS). Due concatenation of the downlinks, the MAC frame on each beam starts at a different moment. We see in FIG. 12, that the beginning of MAC frame for beam B2 is delayed by the duration of the downlink for B1 and that the beginning of MAC frame for B3 is delayed by the duration of B1 plus B2, and so on. As long as the DL sizes on individual bearns are preserved, the MAC frame lengths are constant and equal. Every time the DL size is changed for one beam, all subsequent beams will have a different MAC frame size for one frame, and then, if no more changes occur, they return to the nominal MAC frame size.

In order to support dynamic bandwidth allocation, i.e. to allow variable DL sizes, a MAC management message is sent on each beam every time the MAC frame size for that beam needs to be temporarily changed. The message encodes the difference between the desired MAC frame size and the nominal MAC frame size. This MAC management message is already used by different standards to allow time alignment (synchronization) between base-stations.

The system may also work with fixed bandwidth allocation such that the use of the above-mentioned MAC management message in not needed.

A second method of TDMA access is to produce both the downlink and the uplink for a beam before moving to another beam. With this, there are two distinct arrangements:

-   -   1. All uplinks and downlinks are scheduled within the same MAC         frame.     -   2. Each MAC frame for the transceiver is dedicated to a single         beam, and the beams are circularly accessed one by one during         2^(n) MAC frames. The BS communicates to all SS's a MAC frame         that is 2^(n)-times larger than the actual MAC frame.

One difference between the two arrangements is that, the first allows variable bandwidth distribution between beams while the second does not. However, the second approach allows different transceivers operating with different number of beams to be synchronized without any MAC management message, which does not apply to the first arrangement 

1. A method of beam steering in a wireless network comprising the steps of: generating a first plurality of first signals; distributing the first signals to a first plurality of antennas; and passively steering a first plurality of beams corresponding to the first signals.
 2. A method as claimed in claim 1 wherein each first plurality includes a second plurality.
 3. A method as claimed in claim 1 wherein each first plurality is M, where M is an integer.
 4. A method as claimed in claim 1 wherein the second plurality is 2^(N), where N is an integer.
 5. A method as claimed in claim 2 further comprising the step of forming a beam by providing a corresponding signal from each of the first plurality of signals to the first plurality of antennas.
 6. A method as claimed in claim 1 wherein each first plurality is M, where M is an integer and each first plurality includes a second plurality.
 7. A method as claimed in claim 6 wherein the second plurality is 2^(N), where N is an integer.
 8. A method as claimed in claim 7 further comprising the step of forming a beam by providing a corresponding one of 2^(N) signals from each of the M plurality of 2^(N) signals to a corresponding of the M plurality of 2^(N) antennas.
 9. A method of beam steering in a wireless network comprising the steps of: generating a first plurality of signals, each of the first plurality of signals including a second plurality of signals; distributing the first plurality of signals to a corresponding first plurality of antennas; and passively steering a second plurality of beams.
 10. A method as claimed in claim 9 wherein each first plurality is M, where M is an integer.
 11. A method as claimed in claim 9 wherein the second plurality is 2^(N), where N is an integer.
 12. A method of beam steering in a wireless network comprising the steps of: generating a first plurality of signals, each of the first plurality of signals including a second plurality of signals; distributing the first plurality of signals to a corresponding first plurality of antennas; and passively steering a second plurality of beams.
 13. A method as claimed in claim 12 wherein each first plurality is M, where M is an integer.
 14. A method as claimed in claim 13 wherein the second plurality is 2^(N), where N is an integer.
 15. A method of beam steering in a wireless network comprising the steps of: generating a first plurality of signals, each of the first plurality of signals including a second plurality of signals, each signal compatible with time division multiple access; distributing the first plurality of signals to a corresponding first plurality of antennas; and passively forming a second plurality of beams.
 16. A method as claimed in claim 15 wherein each first plurality is M, where M is an integer.
 17. A method as claimed in claim 16 wherein the second plurality is 2^(N), where N is an integer.
 18. A method of beam steering in a wireless network comprising the steps of: generating a first plurality of signals, each of the first plurality of signals including a second plurality of signals, each signal compatible with time division multiple access; distributing the first plurality of signals to a corresponding first plurality of antennas; and passively steering a second plurality of beams.
 19. A method as claimed in claim 18 wherein each first plurality is M, where M is an integer.
 20. A method as claimed in claim 19 wherein the second plurality is 2^(N), where N is an integer.
 21. Apparatus for beam steering in a wireless network comprising: means for generating a first plurality of first signals; means for distributing the first signals to a first plurality of antennas; and means for passively steering a first plurality of beams corresponding to the first signals.
 22. Apparatus as claimed in claim 21 wherein each first plurality includes a second plurality.
 23. Apparatus as claimed in claim 21 wherein each first plurality is M, where M is an integer.
 24. Apparatus as claimed in claim 21 wherein the second plurality is 2^(N), where N is an integer.
 25. Apparatus as claimed in claim 22 further comprising means for forming a beam including means for providing a corresponding signal from each of the first plurality of signals to the first plurality of antennas.
 26. Apparatus as claimed in claim 21 wherein each first plurality is M, where M is an integer and each first plurality includes a second plurality.
 27. Apparatus as claimed in claim 26 wherein the second plurality is 2^(N), where N is an integer.
 28. Apparatus as claimed in claim 27 further comprising means for forming a beam including means for providing a corresponding one of 2^(N) signals from each of the M plurality of 2^(N) signals to a corresponding of the M plurality of 2^(N) antennas.
 29. Apparatus for beam steering in a wireless network comprising: means for generating a first plurality of signals, each of the first plurality of signals including a second plurality of signals; means for distributing the first plurality of signals to a corresponding first plurality of antennas; and means for passively steering-a second plurality of beams.
 30. Apparatus as claimed in claim 29 wherein each first plurality is M, where M is an integer.
 31. Apparatus as claimed in claim 29 wherein the second plurality is 2^(N), where N is an integer.
 32. Apparatus for beam steering in a wireless network comprising: means for generating a first plurality of signals, each of the first plurality of signals including a second plurality of signals; means for distributing the first plurality of signals to a corresponding first plurality of antennas; and means for passively steering a second plurality of beams.
 33. Apparatus as claimed in claim 32 wherein each first plurality is M, where M is an integer.
 34. Apparatus as claimed in claim 33 wherein the second plurality is 2^(N), where N is an integer.
 35. Apparatus for beam steering in a wireless network comprising: means for generating a first plurality of signals, each of the first plurality of signals including a second plurality of signals, each signal compatible with time division multiple access; means for distributing the first plurality of signals to a corresponding first plurality of antennas; and means for passively forming a second plurality of beams.
 36. Apparatus as claimed in claim 35 wherein each first plurality is M, where M is an integer.
 37. Apparatus as claimed in claim 36 wherein the second plurality is 2^(N), where N is an integer.
 38. Apparatus for beam steering in a wireless network comprising: means for generating a first plurality of signals, each of the first plurality of signals including a second plurality of signals, each signal compatible with time division multiple access; means for distributing the first plurality of signals to a corresponding first plurality of antennas; and means for passively steering a second plurality of beams.
 39. Apparatus as claimed in claim 38 wherein each first plurality is M, where M is an integer.
 40. Apparatus as claimed in claim 39 wherein the second plurality is 2^(N), where N is an integer. 